5-nm Gate-All-Around Transistor Technology With 3-D Stacked Nanosheets

A comprehensive computational study of gate-all-around (GAA) devices with 3-D stacked silicon nanosheets (also known as nanoribbons or nanowires) is presented in this article. Technology development guidelines are provided for low-power applications in 5-nm CMOS technology node and beyond. The 3-D stacked nanosheet devices lower the subthreshold swing, drain-induced barrier-lowering, and subthreshold leakage current by up to 20.75%, 38.89%, and 88.53%, respectively, when compared to a silicon-on-insulator (SOI) FinFET with 5-nm physical gate length and identical silicon area at $V_{DD} = 0.6$ V and T = 80 degrees C. The voltage gain of a minimum-sized CMOS inverter is increased by up to 157% with the 3-D stacked nanosheet devices, thereby providing robust operation with wider noise margins when compared to the SOI-FinFET technology. Furthermore, by scaling the supply voltage to 0.49 V, the energy consumption of a CMOS inverter is reduced by 53.81% with the GAA 3-D stacked nanosheet devices while providing similar output transition speed when compared to the SOI-FinFET technology.